An optical modulator includes an optical phase modulator which applies an operating voltage to at least one arm so as to modulate an optical phase of an optical signal transmitted via at least one arm and an optical phase adjuster which applies a voltage below the operating voltage to at least one arm so as to adjust an operating point. In the optical phase adjuster, an optical phase coarse adjuster applies a voltage below the operating voltage to at least one arm so as to change an optical phase of an optical signal by 180° or more, while an optical phase fine adjuster applies a voltage below the operating voltage to at least one arm so as to changer an optical phase of an optical signal by 90° or less. Thus, it is possible to automatically calibrate an operating point of an optical modulator with low power consumption.
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1. An optical modulator comprising:
an optical branch structure which branches an input light into two optical signals via two arms;
an optical phase modulator which applies an operating voltage to at least one arm so as to modulate an optical phase of an optical signal transmitted via at least one arm;
an optical phase adjuster which applies a voltage below the operating voltage to at least one arm so as to adjust an operating point; and
an optical coupling structure which combines optical signals output from the optical phase adjuster so as to produce an output light,
wherein the optical phase adjuster includes an optical phase coarse adjuster and an optical phase fine adjuster,
wherein the optical phase coarse adjuster applies a voltage below the operating voltage to at least one arm so as to change an optical phase of an optical signal transmitted via at least one arm by 180° or more, and
wherein the optical phase fine adjuster applies a voltage below the operating voltage to at least one arm so as to changer an optical phase of an optical signal transmitted via at least one arm by 90° or less.
8. An operating point control method adapted to an optical modulator, the method comprising:
causing an input light to be branched into two arms in the optical modulator;
applying an operating voltage to an optical waveguide formed in at least one arm of the optical modulator so as to change an optical phase of an optical signal transmitted through the at least one arm;
recombining optical signals undergoing phase changes while being transmitted through the two arms, thus outputting an output light;
measuring a shift of an operating point of the optical modulator by monitoring part of the output light;
applying a voltage below the operating voltage to the optical waveguide formed in the at least one arm so as to change an optical phase of an optical signal transmitted through the at least one arm by 180° or more, thus coarsely calibrating the operating point of the optical modulator based on the measured shift of the operating point; and
applying a voltage below the operating voltage to the optical waveguide formed in the at least one arm so as to change an optical phase of an optical signal transmitted through the at least one arm by 90° or less, thus finely calibrating the operating point of the optical modulator based on the measured shift of the operating point.
2. The optical modulator according to
wherein the silicon-base electro-optic element includes a substrate, a first conductive semiconductor layer having a rib waveguide structure which is formed in a rectangular shape to project in a direction opposite to the substrate, a dielectric layer deposited on the rib waveguide structure, and a second conductive semiconductor layer deposited on the dielectric layer,
wherein the first conductive semiconductor layer is connected to a first electrode wire via a first contact part which is doped with first-conductive impurities at a higher density than other regions,
wherein the second conductive semiconductor layer is connected to a second electrode wire via a second contact part which is doped with second-conductive impurities at a higher density than other regions, and
wherein the first contact part is formed in a rectangular shape to project towards a slab of the first conductive semiconductor layer.
3. The optical modulator according to
4. The optical modulator according to
5. The optical modulator according to
6. The optical modulator according to
7. An optical modulation device comprising the optical modulator as defined in any one of
a power source configured to apply the operating voltage to the optical phase modulator of the optical modulator;
a coarse-adjustment power source configured to apply a voltage below the operating voltage to the optical phase coarse adjuster of the optical modulator;
a fine-adjustment power source configured to apply a voltage below the operating voltage to the optical phase fine adjuster of the optical modulator; and
a monitor configured to monitor a shift of an operating point of the optical modulator in the output light.
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Field of the Invention
The present invention relates to an optical modulator and an operating point control method of an optical modulator.
The present application claims priority on Japanese Patent Application No. 2014-67112, the content of which is incorporated herein by reference.
Description of the Related Art
Optical communication devices operating with wavelengths ranging from 1,310 nm to 1,550 nm have been used for local area networks (LANs) and optical fibers used for household appliances. It is preferable to employ silicon-base optical communication devices in which optical function devices and electronic circuits can be integrated on silicon platforms by way of CMOS technologies.
Silicon-base optical communication devices have been developed and applied to waveguides, optical couplers, wavelength filters, optical modulators, etc. Among them, optical modulators serving as active devices attract attention among engineers. Additionally, it is generally known that Mach-Zehnder interferometers can be applied to optical modulators using changes of refractive indexes. Optical modulators using Mach-Zehnder interferometers are designed to produce optical intensity modulation signals by way of interference using differences of optical phases in arms including two optical waveguides.
Various types of optical devices and optical modulators have been developed and disclosed in various documents. Patent Literature Document 1 discloses an optical phase control circuit which carries out synchronism detection on small modulation components so as to stably control an operating point of an optical modulator. Patent Literature Document 2 discloses a high-speed silicon-base electro-optic modulator. Patent Literature Document 3 discloses an optical waveguide circuit using a Mach-Zehnder interferometer. Patent Literature Documents 4-6 disclose optical modulators. Patent Literature Document 7 discloses a semiconductor laser using optical interference.
Both the arms 101 and 102 have the same length. Without any voltages, no phase differences occur between the arms 101 and 102 so as to superimpose optical signals having the same wavelength, thus maximizing the intensity of light output from the optical coupling structure 104. With a phase difference π occurring between the arms 101 and 102, optical signals transmitted through the arms 101 and 102 are cancelled out when combined together via the optical coupling structure 104, thus minimizing the intensity of light output from the optical coupling structure 104.
Generally speaking, it is possible to maximize an extinction ratio of light by setting an operating point to the intensity of light output from an optical modulator applied with an intermediate voltage between the maximum voltage maximizing the intensity of light and the minimum voltage minimizing the intensity of light. Any one of arms is set to an initial state applied with a voltage causing an optical phase difference corresponding to a half wavelength, and then an operating point (or a reference point) is set to the intensity of light in the initial state. An optical modulator operates based on an operating point so as to output an optical signal. For this reason, it is important to control an operating point constantly. However, it is difficult to stabilize an operating point of an optical modulator due to any changes of environmental temperatures, dispersions of products in manufacturing, and degradation during long-time usage.
Various studies have been carried out to control operating points of optical modulators. Patent Literature Document 1 discloses a technology of controlling an operating point by use of a constant frequency signal superimposed on an operating voltage of a drive circuit causing a phase difference between a first arm and a second arm. Patent Literature Document 5 discloses a technology of controlling an operating point due to a thermo-optic effect using a heater disposed separately from a phase modulator.
For example, operating points may be greatly shifted due to degradation of optical modulators, or operating points may be slightly shifted due to changes of temperatures in optical modulators being driven. The foregoing technologies are unable to control large shifts and small shifts of operating points under low voltages. Additionally, it is difficult to realize optical modulators which can concurrently calibrate large shifts and small shifts of operating points under low voltages.
The technology of Patent Literature Document 1 needs a high voltage above the operating voltage of a drive circuit, causing a phase difference between a first arm and a second arm, since a constant frequency signal is superimposed on the operating voltage of a drive circuit. Since this technology needs to increase the operating voltage of a drive circuit; it is impossible to control an operating point under a low voltage. Additionally, increasing the frequency of a frequency signal superimposed on the operating voltage of a drive circuit may affect the accuracy of phase modulation. In short, this technology is able to solely control a small shift in an operating point of an optical modulator.
The technology of Patent Literature Document 5 utilizing a thermo-optic effect may involve a high phase-change ratio relative to the operating voltage so as to control a large shift in an operating point of an optical modulator. Due to a high phase-change ratio relative to the operating voltage, it is impossible to accurately calibrate a small shift at an operating point of an optical modulator. This may cause a serious problem in mass-produce devices put on the market. It is possible to produce trial products causing high phase-change ratio relative to operating voltages. In trail products, it is possible to calibrate small shifts at operating points by accurately controlling operating voltages. However, it is unpractical to accurately control operating voltages in mass-produce devices put on the market.
It is an object of the present invention to provide an optical modulator and an operating point control method for controlling an operating point of an optical modulator under a low voltage.
In a first aspect, the present invention is directed to an optical modulator including an optical branch structure which branches an input light into two optical signals via two arms; an optical phase modulator which applies an operating voltage to at least one arm so as to modulate an optical phase of an optical signal transmitted via at least one arm; an optical phase adjuster which applies a voltage below the operating voltage to at least one arm so as to adjust an operating point; and an optical coupling structure which combines optical signals output from the optical phase adjuster so as to produce an output light. The optical phase adjuster includes an optical phase coarse adjuster and an optical phase fine adjuster. The optical phase coarse adjuster applies a voltage below the operating voltage to at least one arm so as to change an optical phase of an optical signal transmitted via at least one arm by 180° or more. The optical phase fine adjuster applies a voltage below the operating voltage to at least one arm so as to changer an optical phase of an optical signal transmitted via at least one arm by 90° or less.
In a second aspect, the present invention is directed to an optical modulation device comprising an optical modulator having the above configuration. The optical modulation device further includes a power source configured to apply the operating voltage to the optical phase modulator of the optical modulator; a coarse-adjustment power source configured to apply a voltage below the operating voltage to the optical phase coarse adjuster of the optical modulator; a fine-adjustment power source configured to apply a voltage below the operating voltage to the optical phase fine adjuster of the optical modulator; and a monitor configured to monitor a shift of an operating point of the optical modulator in the output light.
In a third aspect, the present invention is directed to an operating point control method adapted to an optical modulator having the above configuration. The operating point control method includes an optical branch step configured to branch an input light via two arms; an optical modulation step configured to apply an operating voltage to an optical waveguide formed in at least one arm so as to change an optical phase of an optical signal transmitted via at least one arm; an optical coupling step configured to recombine optical signals undergoing phase changes while being transmitted through the two arms, thus outputting an output light; a measurement step configured to measure a shift of an operating point of the optical modulator by monitoring part of the output light; an optical phase coarse adjustment step configured to apply a voltage below the operating voltage to the optical waveguide formed in at least one arm so as to change an optical phase of an optical signal transmitted via at least one arm by 180° or more, thus coarsely calibrating the operating point of the optical modulator based on the shift of the operating point measured in the measurement step; and an optical phase fine adjustment step configured to apply a voltage below the operating voltage to the optical waveguide formed in at least one arm so as to change an optical phase of an optical signal transmitted via at least one arm by 90° or less, thus finely calibrating the operating point of the optical modulator based on the shift of the operating point measured in the measurement step.
According to the present invention, it is possible to calibrate any shifts occurring in an operating point of an optical modulator by use of a low voltage below an operating voltage. Thus, it is possible to realize an optical modulator with low power consumption at low cost. Additionally, it is possible to produce an optical modulation device using an optical modulator while automatically calibrating an operating point of an optical modulator with simple processes.
These and other objects, aspects, and embodiments of the present invention will be described in more detail with reference to the following drawings.
The present invention will be described in further detail by way of examples with reference to the accompanying drawings.
The optical phase coarse adjuster 3A provides a large phase-change value relative to the applied voltage while the optical phase fine adjuster 3B provides a small phase-change value relative to the applied voltage. With the same applied voltage, the optical phase coarse adjuster 3A causes a large phase change while the optical phase fine adjuster 3B causes a small phase change. Owing to the optical phase modulator 3 including the optical phase coarse adjuster 3A and the optical phase fine adjuster 3B, it is possible to calibrate a large shift of an operating point and a small shift of an operating point under the predetermined applied voltage.
Specifically, the optical phase coarse adjuster 3A is able to change the optical phase with an angle of 180° or more by applying a voltage, below the operating voltage of a drive circuit configured to drive the optical phase modulator 2, to at least one arm. Thus, it is possible to calibrate a large shift of an operating point due to an extinction property of light intensity. In contrast, the optical phase fine adjuster 3B is able to change the optical phase with an angle of 90° or less by applying a voltage, below the operating voltage of a drive circuit configured to drive the optical phase modulator 2, to at least one arm. Thus, it is possible to accurately calibrate a small shift of an operating point due to any variation of an environmental temperature at a high-speed drive mode.
Both the optical phase coarse adjuster 3A and the optical phase fine adjuster 3B operate based on a voltage below the operating voltage of a drive circuit for the optical phase modulator 2, wherein it is possible to calibrate a large shift of an operating point and a small shift of an operating point. For this reason, the optical modulator 10 does not need a high power source outputting a high voltage above the operating voltage of a drive circuit for the optical phase modulator 2. In other words, it is unnecessary to connect a high power source to the optical modulator 10, which is thus superior in power consumption and cost performance.
Due to a large optical phase-change value relative to the applied voltage of the optical phase coarse adjuster 3A, the optical phase coarse adjuster 3A may hardly calibrate various shifts of an operating point because it causes a relatively large optical phase change based on a small voltage variation. Therefore, the optical phase coarse adjuster 3A alone is unable to accurately calibrate an operating point.
Due to a small optical phase-change value relative to the applied voltage of the optical phase fine adjuster 3B, the optical phase fine adjuster 3B may hardly calibrate various shifts of an operating point; hence, the optical phase fine adjuster 3B needs a high voltage to calibrate an operating point. This is because it is necessary to cause a large phase change in order to calibrate a large shift of an operating point. The optical phase coarse adjuster 3B, causing a small optical phase-change value relative to the applied voltage, alone cannot cause an adequate phase-change value without a high voltage applied thereto. In this case, it is necessary to use a high operating voltage to control an operating point, which is not preferable in terms of power consumption and cost performance.
In the optical phase adjuster 3, it is possible to arrange the optical phase coarse adjuster 3A and the optical phase fine adjuster 3B for each arm as shown in
In this connection, it is possible to modify the present embodiment as shown in
As the substrate 29 forming an electro-optic element, the present embodiment employs an SOI (Silicon On Insulator) substrate having an oxide film on a silicon substrate; but this is not a restriction. It is possible to use any types of silicon-base substrates.
The SIS-junction silicon-base electro-optic element 20 causes a small phase-change value, having a high linearity, relative to an operating voltage applied thereto. Thus, it is possible to accurately control a phase-change value based on the applied voltage. Additionally, it is possible to exhibit one-to-one correspondence between the optical phase-change value and the applied voltage; this may reduce complexity of an element. Due to a small phase-change value having a high linearity, it is possible to prevent a large shift from occurring in an operating point.
A voltage applied to each arm may change an optical phase of each arm in the optical phase modulator 2. A drive circuit may produce a voltage of 3.3 V with respect to the optical phase modulator 2 using SiGe bipolar transistors. Alternatively, a drive circuit may produce a voltage ranging from 1.0 V to 1.8 V with respect to the optical phase modulator 2 using a CMOS structure. An actual voltage applied to the optical phase modulator 2 changing an optical phase may become lower than the operating voltage of a drive circuit.
The SIS-junction silicon-base electro-optic element 20 utilizes an electro-optic effect (or a free carrier plasma effect). The outline of an optical phase modulation mechanism, i.e. an operating principle of the SIS-junction silicon-base electro-optic element 20, will be described below.
A pure electro-optic effect cannot be obtained or hardly obtained in silicon; hence, an optical phase modulation may utilize a free carrier plasma effect and a thermo-optic effect. Herein, a free carrier plasma may solely suffice the needs of the present invention aiming at a high-speed operation (e.g. a speed of Giga-bits per second or more). The present invention uses changes of refractive indexes in silicon layers, which can be explained using first-order approximations, i.e. Equations 1, 2 as follows.
In the above, Equation 1 denotes a real part of a refractive-index change in a silicon layer while Equation 2 denotes an imaginary part of a refractive-index change in a silicon layer, wherein e denotes an electric charge, λ denotes a wavelength of light, ∈0 denotes a dielectric constant in vacuum, n denotes a refractive index of a silicon layer, me denotes an effective mass of an electron carrier, mh denotes an effective mass of a hole carrier, μe denotes mobility of an electron carrier, μh denotes mobility of a hole carrier, ΔNe denotes a density change of electron carriers, and ΔNh denotes a density change of hole carriers.
Various experimental evaluations have been carried out with respect to electro-optic effects in silicon, wherein it is known that Drude equations are consistent with refractive-index changes at carrier densities using wavelengths of 1,310 nm to 1,550 nm used for optical communications. In electro-optic elements using this theory, it is possible to define a phase-change value Δθ via Equation 3.
In Equation 3, L denotes the length of an active layer (i.e. an effective modulation region) in an optical propagation direction in a silicon-base electro-optic element while Δneff denotes an effective refractive index which can be obtained from Δn and Δk. According to Equation 3, it is possible to produce a large phase change using a large change of an effective refractive index Δneff irrespective of a short length L of an active layer.
The silicon-base electro-optic element 20 includes the rib waveguide structure 21a by which the optical waveguide may overlap with a region causing a change of a refractive index; hence, it is possible to increase optical modulation efficiency relative to the voltage applied to the silicon-base electro-optic element 20. Thus, it is possible to reduce the length of an active layer subjected to optical modulation, and therefore it is possible to miniaturize optical modulators.
The optical waveguide indicates a region of guiding light. In
Due to the formation of the rib waveguide structure 21a, it is possible to reduce the overlap between the optical waveguide and the region doped with impurities at a high density.
The region doped with impurities at a high density (hereinafter, simply referred to a highly doped region) embraces the first contact part 24 and the second contact part 26 in
It is possible to produce a thickness W of a region causing a change in a carrier density (i.e. the maximum thickness of a depletion layer) in the heat balance condition via Equation 4.
In Equation 4, ∈s denotes a dielectric constant of a semiconductor layer, k denotes a Boltzmann constant, Nc denotes a carrier density, ni denotes an intrinsic carrier density, and e denotes an electric charge. When Nc is 1017/cm3, for example, the maximum thickness of a depletion layer is about 0.1 μm. An increased carrier density may reduce the thickness of a depletion layer, i.e. the thickness of a region causing a change in a carrier density.
For this reason, it is preferable that the height of the rib waveguide structure 21a be equal to or higher than W. Using the rib waveguide structure 21a with the height above W, it is possible to confine the region causing a change in a carrier density within the rib waveguide structure 21a, thus maintaining large overlap with the optical waveguide.
The first conductive semiconductor layer 21 is connected to the first electrode wire 25 via the first contact part 24 which is doped with first-conductive impurities at a higher density than other regions. Similarly, the second conductive semiconductor layer 23 is connected to the second electrode wire 27 via the second contact part 26 which is doped with second-conductive impurities at a higher density than other regions. High-density doping may reduce contact resistances at the boundary between the first conductive semiconductor layer 21 and the first electrode wire 25 and at the boundary between the second conductive semiconductor layer 23 and the second electrode wire 27. In result, it is possible to reduce series resistance components while reducing RC time constants. This may improve the speed of an optical modulation.
The first contact part 24 rectangularly shaped to project towards the slab 21c of the first conductive semiconductor layer 21. Thus, it is possible to increasing a doping density of the first contact part 24 while reducing contact resistance at the boundary between a semiconductor and a conductor. That is, it is possible to reduce RC time constants, thus increasing the speed of an optical modulation.
Additionally, it is possible to reduce the width of the slab 21c by rectangularly projecting the first contact part 24. Herein, the thickness of the slab 21c is reduced to about 0.1 μm in order to reduce the overlap between the highly doped region and the optical waveguide. However, it is difficult to uniformly reduce the thickness of the slab 21c in a wide area.
It is preferable that each of the first conductive semiconductor layer 21 and the second conductive semiconductor layer 23 be formed using a single layer made of materials selected from among polycrystalline silicon, amorphous silicon, distortion silicon, monocrystalline silicon, and Si1−xGex.
The optical phase coarse adjuster 3A may be greatly changed in phase relative to the applied voltage. Specifically, it may cause a phase change of 180° or more relative to the operating voltage of a drive circuit configured to drive the optical phase adjuster 3. For this reason, it is preferable to form the optical phase coarse adjuster 3A by means of a silicon-base electro-optic element using a thermo-optic effect or a carrier injection silicon-base electro-optic element using a carrier plasma effect.
The silicon-base electro-optic element 30 using a thermo-optic effect includes a substrate 39, an intrinsic semiconductor layer 31 having a rib waveguide structure 31a rectangularly shaped to project in a direction opposite to the substrate 39, a dielectric layer 32 deposited on the rib waveguide structure 31a, and a high-resistance polycrystalline semiconductor layer 33 deposited on the dielectric layer 32. The intrinsic semiconductor layer 31 and the high-resistance polycrystalline semiconductor layer 33 are connected to a first electrode wire 35 and a second electrode wire 37 via a contact part 34 which is doped with first-conductive impurities or second-conductive impurities at a higher density than other regions. A clad layer 38 made of oxides is formed in other regions so as to limit the optical waveguide. A voltage applied to the second electrode wire 37 may heat the high-resistance polycrystalline semiconductor layer 33 so as to change a refractive index of the intrinsic semiconductor layer 31. In the silicon-base electro-optic element 30 using a thermo-optic effect, the optical waveguide corresponds to a region L2 encompassed by dotted lines in
The carrier injection silicon-base electro-optic element 40 using a carrier plasma effect includes a substrate 49 and an intrinsic semiconductor layer 41 having a rib waveguide structure 41a rectangularly shaped to project in a direction opposite to the substrate 49. A first contact part 44 which is doped with first-conductive impurities at a higher density than other regions is formed in proximity to one end of the intrinsic semiconductor layer 41. The intrinsic semiconductor layer 41 is connected to a first electrode wire 45 via the first contact part 44. A second contact part 46 which is doped with second-conductive impurities at a higher density than other regions is formed in proximity to the other end of the intrinsic semiconductor layer 41. The intrinsic semiconductor layer 41 is connected to a second electrode wire 47 via the second contact part 46. A clad region 48 made of oxides is formed in other regions so as to limit the optical waveguide. A voltage applied between the first electrode wire 45 and the second electrode wire 47 may change a refractive index of the intrinsic semiconductor layer 41 (mainly, the rib waveguide structure 41a). In the silicon-base electro-optic element 40 using a carrier plasma effect, the optical waveguide corresponds to a region L3 encompassed by dotted lines in
The silicon-base electro-optic element 50 using a carrier plasma effect includes a substrate 59, an intrinsic semiconductor layer 51 having a rib waveguide structure 51a rectangularly shaped to project in a direction opposite to the substrate 59, a dielectric layer 52 deposited on the rib waveguide structure 51a, and a second intrinsic semiconductor layer 53 deposited on the dielectric layer 52. The intrinsic semiconductor layer 51 is connected to first electrode wires 55 via a first contact part 54 which is doped with first-conductive impurities at a higher density than other regions. The second intrinsic semiconductor layer 53 is connected to second electrode wires 57 via a second contact part 56a and a third contact part 56b which are disposed in proximity to the opposite ends of the second intrinsic semiconductor layer 53. The second contact part 56a is doped with first-conductive impurities at a higher density than other regions while the third contact part 56b is doped with second-conductive impurities at a higher density than other regions. A clad layer 58 made of oxides is formed in other regions so as to limit the optical waveguide. A voltage applied between the first electrode wires 55 and the second electrode wires 57 may change refractive indexes of the intrinsic semiconductor layer 51 and the second intrinsic semiconductor layer 53. In the carrier injection silicon-base electro-optic element 50 using a carrier plasma effect, the optical waveguide corresponds to a region L4 encompassed by dotted lines in
The optical phase fine adjuster 3B is slightly changed in phase based on the applied voltage. Specifically, the optical phase fine adjuster 3B may cause a phase change of 90° or less relative to the operating voltage of a drive circuit configured to drive the optical phase modulator 2. For this reason, it is preferable that the optical phase fine adjuster 3B be formed by means of a carrier depletion silicon-base electro-optic element using a carrier plasma effect or the SIS junction silicon-base electro-optic element 20 used for the optical phase modulator 2.
In the silicon-base electro-optic element 30 using a thermo-optic effect, it is possible to separate the high-resistance polycrystalline semiconductor layer 33 from the rib waveguide structure 31a. The distance between the high-resistance polycrystalline semiconductor layer 33 and the rib waveguide structure 31a depends on the applied voltage. By modifying the silicon-base electro-optic element 30 such that the high-resistance polycrystalline semiconductor layer 33 is separated from the rib waveguide structure 31a by a distance of 2.0 μm or more with respect to the applied voltage of 1.8 V, for example, it is possible to achieve an optical phase fine adjuster with a phase-change value of 90° or less.
In the carrier depletion silicon-base electro-optic element 60 using a carrier plasma effect, a first conductive semiconductor layer 61 horizontally joins a second conductive semiconductor layer 63 above a substrate 69. The first conductive semiconductor layer 61 is coupled with the second conductive semiconductor layer 63 to form a rib waveguide structure rectangularly shaped to project in a direction opposite to the substrate 69. A dielectric layer 62 is deposited on the rib waveguide structure. The first conductive semiconductor layer 61 is connected to a first electrode wire 65 via a first contact part 64 which is doped with first-conductive impurities at a higher density than other regions. The second conductive semiconductor layer 63 is connected to a second electrode wire 67 via a second contact part 66 which is doped with second-conductive impurities at a higher density than other regions. A clad layer 68 made of oxides is formed in other regions so as to limit the optical waveguide. A voltage applied between the first electrode wire 65 and the second electrode wire 67 may change a refractive index via a depletion layer formed at the boundary between the first conductive semiconductor layer 61 and the second conductive semiconductor layer 63. In the carrier depletion silicon-base electro-optic element 60 using a carrier plasma effect, the optical waveguide corresponds to a region L5 encompassed by dotted lines in
The concrete configurations of the optical phase modulator 2 and the optical phase adjuster 3 have been described above. In this connection, it is preferable that the optical phase modulator 2 and the optical phase adjuster 3 be electrically separated from each other but optically connected together. Specifically, it is preferable that the optical waveguide of each arm of the optical phase modulator 2 be separated from the optical waveguide of each arm of the optical phase adjuster 3 while these optical waveguides are connected together via semiconductor materials. Additionally, it is preferable that the optical waveguide of each arm of the optical phase modulator 2 be directed toward the optical phase adjuster 3 while the distal end thereof be shaped to project with a width corresponding to a half wavelength of light or less. Similarly, it is preferable that the optical waveguide of each arm of the optical phase adjuster 3 be directed toward the optical phase modulator 2 while the distal end thereof is shaped to project with a width corresponding to a half width of light or less. Moreover, it is preferable that the projected distal end of the optical waveguide of the optical phase modulator 2 be disposed close to the projected distal end of the optical waveguide of the optical phase adjuster 3 within a distance of effusing evanescent waves.
It is impossible to achieve an optical waveguide function when the optical phase modulator 2 is optically separated from the optical phase adjuster 3. To secure an optical waveguide function, it is necessary to connect the optical phase modulator 2 to the optical phase adjuster 3. Herein, an electric current may unexpectedly flow between the optical phase modulator 2 and the optical phase adjuster 3 depending on a difference between voltages applied to the optical phase modulator 2 and the optical phase adjuster 3. This electric current may cause noise with respect to phase modulation and phase adjustment. Therefore, it is preferable that the optical phase modulator 2 be electrically separated from the optical phase adjuster 3.
Next, an optical modulator in which the optical phase modulator 2 and the optical phase adjuster 3 are electrically separated from each other but optically connected together will be described below. Herein, the optical waveguide of each arm of the optical phase modulator 2 is separated from the optical waveguide of each arm of the optical phase adjuster 3 but these optical waveguides are connected together via semiconductor materials.
As shown in
The optical waveguide L1 of the SIS junction silicon-base electro-optic element 20 and the optical waveguide L3 of the carrier injection silicon-base electro-optic element 40 are shaped to mutually project thereto but separated from each other with an arbitrary distance, thus achieving an electric isolation. However, a light waveguide function is broken between the optical waveguide L1 and the optical waveguide L3 which are separated from each other by an arbitrary distance. For this reason, it is necessary to connect the optical waveguides L1 and L3 together via a semiconductor material D having an insulating ability and a light waveguide function. The semiconductor material D having an insulating ability may not affect an electric isolation between the optical waveguides L1 and L3. Herein, it is necessary for the semiconductor material D to demonstrate an insulating ability which may block an electric current from flowing between the optical waveguides L1 and L3 irrespective of a potential difference of several volts applied between the optical waveguides L1 and L3.
An optical signal output from the optical waveguide L1 of the SIS junction silicon-base electro-optic element 20 can be guided to the optical waveguide L3 of the carrier injection silicon-base electro-optic element 40 via the semiconductor material D. For example, it is possible to form the semiconductor material D using a material selected from among polycrystalline silicon, amorphous silicon, distortion silicon, and Si1−xGex.
All the optical waveguides are not necessarily connected together, but they need to be partially connected together. Specifically, it is possible to connect the rib waveguide structure 21a or the second conductive semiconductor layer 23 of the SIS junction silicon-base electro-optic element 20 to the counterpart optical waveguide.
Since the dielectric layer 22 of the optical waveguide L1 is formed using the same material as the semiconductor material D, it is possible to connect the optical waveguides L1 and L3 together by simply extending the dielectric layer 22. In this case, it is unnecessary to form a new layer serving as the semiconductor material D configured to connect the optical waveguides L1 and L3 together; hence, it is possible to easily produce an optical modulator.
Next, another example of an optical modulator in which an optical phase modulator and an optical phase adjuster are electrically separated from each other but optically connected together will be described below. Herein, the optical waveguide of each arm of the optical phase modulator is projected towards the optical phase adjuster while the distal end thereof is reduced in width to a half wavelength of light or less. Similarly, the optical waveguide of each arm of the optical phase adjuster is projected towards the optical phase modulator while the distal end thereof is reduced in width to a half wavelength of light or less.
As shown in
The optical waveguide L1 of the SIS junction silicon-base electro-optic element 20 is directed towards the carrier injection silicon-base electro-optic element 50 while the distal end thereof is shaped to project with a width corresponding to a half wavelength of light or less. Similarly, the optical waveguide L4 of the carrier injection silicon-base electro-optic element 50 is directed towards the SIS junction silicon-base electro-optic element 20 while the distal end thereof is shaped to project with a width corresponding to a half wavelength of light or less.
Light incident on the SIS junction silicon-base electro-optic element 20 is transmitted through the optical waveguide L1 and guided towards the projected distal end. The incident light cannot be guided by the distal end whose width is reduced to a half wavelength of light or less, whereas evanescent waves may occur in a region transmitting a wavelength of light or less. Herein, evanescent waves will be reemitted as light when a specific material able to guide light is put close to a region transmitting evanescent waves just before being attenuated. Since the optical waveguide L1 of the SIS junction silicon-base electro-optic element 20 is disposed close to the optical waveguide L4 of the carrier injection silicon-base electro-optic element 50 within a distance of effusing evanescent waves, it is possible to guide the incident light of the SIS junction silicon-base electro-optic element 20 to the carrier injection silicon-base electro-optic element 50 by way of evanescent waves. In contrast, it is possible to block any electric signals from flowing between the electro-optic elements 20 and 50 because their distal ends are physically separated from each other. Owing to the aforementioned structure, it is possible to realize an optical modulator in which an optical phase modulator and an optical phase adjuster are electrically isolated from each other but optically connected together.
The projected part (or the distal end) is not necessarily formed in the entirety of an optical waveguide but can be formed in part of an optical waveguide. Specifically, it is possible to form the projected part in either the rib waveguide structure 21a or the second conductive semiconductor layer 23 in the SIS junction silicon-base electro-optic element 20. Additionally, it is possible to form the projected part in either the intrinsic semiconductor layer 51 or the second intrinsic semiconductor layer 53 in the carrier injection silicon-base electro-optic element 50. Moreover, it is possible to employ the cross-sectional structure of
Next, a manufacturing method of an SIS junction silicon-base electro-optic element 20 will be described with reference to
A semiconductor layer (i.e. a first conductive semiconductor layer 21) is formed close to the deposition plane of the substrate 29. Herein, the first conductive semiconductor layer 21 can be subjected to impurity doping (or ion injection) using boron, phosphorus, or arsenic before or after manufacturing the substrate 29.
Next, as shown in
In the above, it is possible to employ either wet etching or dry etching. Herein, it is necessary to adjust etching conditions such that the area of slab 21c will not be completely removed from the first conductive semiconductor layer 21. It is possible to adjust etching conditions by changing temperatures. It is preferable that the thickness of the slab 21c range from 50 nm to 150 nm.
As shown in
Next, a film forming method such as a plasma CVD (Chemical Vapor Deposition) method is implemented to temporarily form the oxide-film clad layer 28 covering the first conductive semiconductor layer 21 and the dielectric layer 22. As shown in
As shown in
As shown in
The power source 101 applies a voltage to the optical phase modulator 2 so as to change an optical phase of light being guided by the optical modulator 10. At this time, the monitor 104 is used to confirm a shift of an operating point of the optical modulator 10 due to a phase change of light.
The coarse-adjustment power source 102 and the fine-adjustment power source 103 apply voltages to the optical phase coarse adjuster 3A and the optical phase fine adjuster 3B based on a shift of an operating point of the optical modulator 10 which is confirmed with the monitor 104. In this connection, the voltages of the power sources 102 and 103 are equal to or lower than the voltage of the power source 101.
For this reason, the optical modulation device 100 does not necessarily include a high power source which is able to output a higher voltage than the voltage of the power source 101; hence, it is possible to achieve low power consumption. Thus, it is possible to produce the optical modulation device 100 at low cost without using an expensive high power source.
The present invention needs a simple operation to measure a shift of an operating point of the optical modulator 10 with the monitor 104, which is not necessarily limited in structure. Thus, it is possible to use a generally-known photo-diode monitor.
Next, an operating point control method will be described below. The operating point control method is used to control an operating point of an optical modulator via the following steps.
An optical branch step is carried out to branch the input light into two optical signals via two optical waveguides. An optical modulation step is carried out to apply a voltage to at least one optical waveguide so as to change an optical phase of an optical signal being guided by at least one optical waveguide. An optical coupling step is carried out to combine optical signals which are each changed in optical phase. A measurement step is carried out to monitor a shift of an operating point of an optical modulator with a monitor configured to monitor part of the combined light. An optical phase coarse adjustment step and an optical phase fine adjustment step are carried out to calibrate an operating point of an optical modulator based on a shift of an operating point measured with a monitor. It is possible to manually calibrate an operating point of an optical modulator. However, it is preferable to automatically calibrate an operating point of an optical modulator with a processor and a drive circuit. Specifically, the processor processes a shift of an operating point of an optical modulator measured with a monitor, and then the drive circuit automatically produces a voltage corresponding to a shift of an operating point. That is, the optical phase coarse adjustment step applies a voltage, below an operating voltage of a drive circuit, to an optical phase adjuster so as to change the optical phase of light by 180° or more, while the optical phase fine adjustment step applies a voltage, below an operating voltage of a drive circuit, to an optical phase adjuster so as to change the optical phase of light by 90° or less.
Due to the optical branch step, the input light of an optical modulator is branched into two optical signals with the same phase.
The optical modulation step is carried out to change an optical phase of at least one optical signal which is branched from the input light. An optical phase change occurs due to a change in a refractive index of an optical waveguide applied with a voltage. The optical coupling step recombines optical signals which are each changed in optical phase. It is possible to modulate the intensity of the output light due to a optical phase change. In other words, it is possible to replace an electric signal, based on the operating voltage of a drive circuit, with an optical signal. Since an optical phase difference occurring in the optical coupling step directly affects an optical signal output from an optical modulator, the optical modulation step may change the optical phases of two optical signals or the optical phase of one optical signal.
It is possible to detect an optical phase difference occurring in the optical modulation step by measuring part of the output light combined in the optical coupling step. Additionally, it is possible to measure a shift of an operating point of an optical modulator based on a shift between the naturally occurred phase difference and the measured phase difference of the output light. The above measurement is carried out such that the combined light is subjected to branching again so as to introduce part of the combined light to a photo-diode monitor.
As described above, it is possible to calibrate the measured shift of an operating point of an optical modulator by way of the optical phase coarse adjustment step and the optical phase fine adjustment step.
The optical phase coarse adjustment step is carried out to apply a voltage, below the operating voltage of a drive circuit in the optical modulation step, to an optical adjuster so as to change an optical phase of an optical signal by 180° or more. Additionally, the optical phase fine adjustment step is carried out to apply a voltage, below the operating voltage of a drive circuit in the optical modulation step, to an optical adjuster so as to change an optical phase of an optical signal by 90° or less. In short, the optical phase coarse adjustment step is able to calibrate a large shift of an operating point of an optical modulator, while the optical phase fine adjustment step is able to calibrate a small shift of an operating point of an optical modulator.
That is, it is possible to handle a large shift and a small shift occurring in an operating point of an optical modulator by simply applying a voltage, below the operating voltage of a drive circuit in the optical phase modulation step, to an optical phase adjuster.
Next, characteristics of phase changes depending on applied voltages in silicon-base electro-optic elements will be described with reference to graphs of
Specifically, a phase change of 180° or more occurs in the carrier injection silicon-base electro-optic element 50 having the length of 200 μm and applied with a voltage of 1.5 V. Only a phase change of 9° occurs in the SIS junction silicon-base electro-optic element 20 having the length of 200 μm and applied with a voltage of 1.5 V. The optical phase modulator 2 using a CMOS structure needs a drive circuit producing an operating voltage of 1.8V.
Therefore, it is possible to use the carrier injection silicon-base electro-optic element 50 for the optical phase coarse adjuster 3A while using the SIS junction silicon-base electro-optic element 20 for the optical phase fine adjuster 3B. The SIS junction silicon-base electro-optic element 20 demonstrates relatively linear phase changes, and therefore the electro-optic element 20 may effectively work to finely adjust phase changes.
Lastly, the present invention is not necessarily limited to the foregoing embodiments and examples, which can be further modified in various ways within the scope of the invention as defined in the appended claims.
Takahashi, Shigeki, Fujikata, Junichi
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